Measuring language learning environments in secondary science classrooms

The purpose of this study was to explore a new learning environment instrument which could be used by teaching practitioners and other educators to measure the language learning environment in the secondary science classroom. The science teacher is central in creating science classrooms conductive to the language needs of students and should be promoting the learning of language in the science curriculum and in the teaching strategies with English as second language learners. The data in this study were collected using a structured self-administered survey with a sample of 240 secondary school students from eight science classrooms. Factor analysis identified five dimensions, namely, Teacher Support, Vocabulary Development, Assessment, Motivation and Language for Learning Science. These five dimensions explained 56.9% of the variance in the language learning environment instrument. The internal reliability of the dimensions using Cronbach’s α ranged from 0.603 to 0.830. The study revealed significant differences in the dimensions of the language learning environment between what the students perceived to actually be occurring to what they would prefer. Implications from this preliminary research include the ability for measuring the language learning environment in the secondary science class and the potential for practitioners to use the information to develop teaching strategies conducive to learning for all students.     

Field-study science classrooms as positive and enjoyable learning environments

We investigated differences between field-study classrooms and traditional science classrooms in terms of the learning environment and students’ attitudes to science, as well as the differential effectiveness of field-study classrooms for students differing in sex and English proficiency. A modified version of selected scales from the What Is Happening In this Class? questionnaire was used to assess the learning environment, whereas students’ attitudes were assessed with a shortened version of a scale from the Test of Science Related Attitudes. A sample of 765 grade 5 students from 17 schools responded to the learning environment and attitude scales in terms of both their traditional science classrooms and classrooms at a field-study centre in Florida. Large effect sizes supported the effectiveness of the field-studies classroom in terms of both the learning environment and student attitudes. Relative to the home school science class, the field-study class was considerably more effective for students with limited English proficiency than for native English speakers.     

Relationship between perceived and observed student-centred learning environments in Qatari elementary mathematics and science classrooms

Recently, Qatar established educational reform in charter (independent) schools focusing on curriculum standards, student-centred teaching, standards-based assessment, English as the language of instruction, and extensive professional development. A primary area of emphasis was the creation of student-centred mathematics and science classrooms characterised by inquiry and active student participation. The purpose of this study was to investigate differences in the learning environments of Qatari mathematics and science classrooms at two levels: in higher- and lower-performing Qatari schools implementing the recent Education for a New Era reform elements; and in classes of teachers who experienced professional development focused on student-centred teaching strategies and those who did not. Participants included teachers and students in 47 grade 3 and 4 mathematics and science classrooms. Classroom observations were conducted and student learning environment surveys were administered at the beginning and end of the semester. Results indicated low levels of student-centred instruction, despite significant improvement over time. Few differences by level of school performance or professional development participation existed. However, Personalisation emerged as a key learning environment variable related to teachers’ implementation of student-centred instruction.     

Teaching and learning science in linguistically diverse classrooms

In this paper we reflect on the article, Science education in a bilingual class: problematising a translational practice, by Zeynep Ünsal, Britt Jakobson, Bengt-Olav Molander and Per-Olaf Wickman (Cult Stud Sci Educ, doi: 10.1007/s11422-016-9747-3). In their article, the authors present the results of a classroom research project by responding to one main question: How is continuity between everyday language and the language of science construed in a bilingual science classroom where the teacher and the students do not speak the same minority language? Specifically, Ünsal et al. examine how bilingual students construe relations between everyday language and the language of science in a class taught in Swedish, in which all students also spoke Turkish, whereas the teacher also spoke Bosnian, both being minority languages in the context of Swedish schools. In this forum, we briefly discuss why close attention to bilingual dynamics emerging in classrooms such as those highlighted by Ünsal et al. matters for science education. We continue by discussing changing ontologies in relation to linguistic diversity and education more generally. Recent research in bilingual immersion classroom settings in so-called “content” subjects such as Content and Language Integrated Learning, is then introduced, as we believe this research offers some significant insights in terms of how bilingualism contributes to knowledge building in subjects such as science. Finally, we offer some reflections in relation to the classroom interactional competence needed by teachers in linguistically diverse classrooms. In this way, we aim to further the discussion initiated by Ünsal et al. and to offer possible frameworks for future research on bilingualism in science education. In their article, Ünsal et al. conclude the analysis of the classroom data by arguing in favor of a translanguaging pedagogy, an approach to teaching and learning in which students’ whole language repertoires are used as valuable resources for constructing meaning and for developing academic competences in the language of instruction. This is a conclusion that we support wholeheartedly and an educational practice that we hope to promote with this forum discussion.     

Technology-supported learning innovation in cultural contexts

Many reform initiatives adopt a reductionist, proceduralized approach to cultural change, assuming that deep changes can be realized by introducing new classroom activities, textbooks, and technological tools. This article elaborates a complex system perspective of learning culture: A learning culture as a complex system involves macro-level properties (e.g., epistemological beliefs, social values, power structures) and micro-level features (e.g., technology, classroom activities). Deep changes in macro-level properties cannot be reduced to any component. This complex system perspective is applied to examining technology-supported educational change in East Asia and analyzing how teachers sustain the knowledge building innovation in different contexts. Working with the macro–micro dynamics in a learning culture requires a principle-based approach to learning innovation that specifies macro-level changes using principle-based instead of procedure-based terms and engages teachers’ deep reflection and creative engagement at both the macro- and the micro-level.     

Building computer supported collaborative learning environments in early childhood classrooms

Educational technology research and development - A Multi-touch table functions as a tablet, but allows multiple children to move around and manipulate the screen simultaneously. Using social...     

Interactive pedagogy and subsequent effects on learning in science classrooms

Observations of pupils‐in‐action whilst carrying out investigations indicated that there was plenty of social and cooperative exchange. There was, however, infrequent discussion regarding the planning of experimental approaches, predicting outcomes, consideration of the meaning of evidence and evaluation of task solutions. These observations informed the nature of interactive in‐service programmes developed in Keele University Education Department. Professional development was designed to purposely illustrate a wide repertoire of pedagogic strategies that focused around these issues to support cognitive development of pupils. The interactive nature of the in‐service training was shown to affect widespread ‘change in teachers’ practice. These teachers, involved in experiential in‐service, reflected that they intervened more regularly in children's learning. Their engagement in in‐service training as learners in problem‐solving situations resulted in conceptual shifts in understanding the learning processes their pedagogical transformations could affect. The impact of this changed praxis on pupils' learning in investigational situations was studied after in‐service intervention. These findings were compared with the performance of pupils of the same year group carrying out the same investigations before in‐service intervention. The more interactive nature of the teachers' changed pedagogy appeared to affect change in the way pupils themselves interacted and learnt from and with each other. Explicitly sharing subjective views through exploratory talk was found to be important to affect learning through social interaction.     

Learning environments associated with technology-based science classrooms for gifted Singaporean females

Because there has been very little past research into gifted students’ science learning environments, especially in Singapore, we selected from four established questionnaires six learning environment scales that are consistent with Van Tassel-Baska and Stambaugh’s guidelines for gifted education. These scales were modified slightly to enhance suitability for the target population and refined further based on feedback from teachers and students in a pilot study. Data from administration of the questionnaires to 722 gifted science students in grades 9 and 10 were analysed to provide support for the questionnaire’s factorial validity, internal consistency reliability, ability to differentiate between classrooms, and predictive validity (in terms of associations with self-efficacy). To evaluate a new one-student one-laptop program being implemented for the first time, we compared the learning environments of this program with regular classrooms and found higher levels of perceived investigation, task orientation, collaboration, computer usage and formative assessment in technology-based classrooms.

     

Students' science perceptions and enrollment decisions in differing learning cycle classrooms

This investigation examined 10th‐grade biology students' decisions to enroll in elective science courses, and explored certain attitudinal perceptions of students that may be related to such decisions. The student science perceptions were focused on student and classroom attitudes in the context of differing learning cycle classrooms (high paradigmatic/high inquiry, and low paradigmatic/low inquiry). The study also examined possible differences in enrollment decisions/intentions and attitudinal perceptions among males and females in these course contexts. The specific purposes were to: (a) explore possible differences in students' decisions, and in male and female students' decisions to enroll in elective science courses in high versus low paradigmatic learning cycle classrooms; (b) describe patterns and examine possible differences in male and female students' attitudinal perceptions of science in the two course contexts; (c) investigate possible differences in students' science perceptions according to their decisions to enroll in elective science courses, participation in high versus low paradigmatic learning cycle classrooms, and the interaction between these two variables; and (d) examine students' explanations of their decisions to enroll or not enroll in elective science courses. Questionnaire and observation data were collected from 119 students in the classrooms of six learning cycle biology teachers. Results indicated that in classrooms where teachers most closely adhered to the ideal learning cycle, students had more positive attitudes than those in classrooms where teachers deviated from the ideal model. Significantly more females in high paradigmatic learning cycle classrooms planned to continue taking science course work compared with females in low paradigmatic learning cycle classrooms. Male students in low paradigmatic learning cycle classrooms had more negative perceptions of science compared with males in high paradigmatic classrooms, and in some cases, with all female students. It appears that using the model as it was originally designed may lead to more positive attitudes and persistence in science among students. Implications include the need for science educators to help teachers gain more thorough understanding of the learning cycle and its theoretical underpinnings so they may better implement this procedure in classroom teaching. © 2001 John Wiley & Sons, Inc. J Res Sci Teach 38: 1029–1062, 2001     

Assessing culturally sensitive factors in the learning environment of science classrooms

As schools are becoming increasingly diverse in their scope and clientele, any examination of the interaction of culturally sensitive factors of students' learning environments with learning science assumes critical importance. The purpose of this exploratory study was to develop an instrument to assess learning environment factors that are culturally sensitive, to provide initial validation information on the instrument and to examine associations between students' perceptions of their learning environments and their attitudes towards science and achievement of enquiry skills. A measure of these factors of science student's learning environment, namely the Cultural Learning Environment Questionnaire (CLEQ), was developed from past learning environment instruments and influenced by Hofstede's four dimensions of culture (Power Distance, Uncertainty Avoidance, Individualism, and Masculinity/Femininity). The reliability and discriminant validity for each scale were obtained and associations between learning environment, attitude to science and enquiry skills achievement were found.     

Alternative perspectives on authentic learning environments in elementary science

There are multiple views of a learning environment, each having the potential to contribute to our understanding and valuing of learning. In this study, the teacher's view was positive, concerned with children's ownership of ideas and positive self esteem, and based primarily on a view that in order to learn, students need to be actively engaged in activities that are enjoyable and challenging. The researcher had two perspectives, both differing from the teacher's. Consistent with social constructivism the students interacted freely with one another, learned about structures, and produced models that reflected their goals. From this perspective the learning environment was rich. But there was something missing in this classroom — the utilization of resources to assist in reproducing the culture of science. From the perspective of cultural reproduction the learning environment was impoverished.Present approaches to the study of learning environments are grounded in a tradition of using questionnaires to elicit perceptions of the experiences and preferences of students and teachers in terms of constructs selected for their salience to researchers. Although these constructs have changed over the past 20 to 30 years to reflect theoretical models applied to the teaching and learning of science, the use of different methods and theories in the study of learning environments, particularly in elementary grades, offers the promise of improving the quality of learning and teaching science. Studies of elementary students undertaken by Roth and his colleagues in Canada (e.g., Roth, 1996) and Ritchie and Hampson (1996) in Australia are particularly relevant to this chapter. The studies have yielded implications for teaching and learning in terms of fresh theoretical perspectives based on the use of qualitative approaches to the study of learning environments in which technology was used to build ideas about canonical science.When Ms. Scott was first approached about participating in a study she agreed and suggested that building castles would provide a suitable context. Her grade 2 classroom was in an elementary school in the northern part of Florida and contained students from diverse socioeconomic backgrounds. The ethnic composition of the school was approximately 60% Caucasian and 25% African American with the remaining 15% consisting of Asian American and Hispanic students. Few students in grade 2 had limited English proficiency.The interpretative research methods used accessed multiple data sources and were responsive to experiences during intensive visits to the grade two classroom during a three week sequence of activities. Ms. Scott and her students were given multiple opportunities to discuss their roles in their own language. Artifacts from the classroom were collected and intensive analyses of videotapes and 35 mm photographs taken by the teacher were undertaken. This chapter is based on complementary perspectives which are presented in the next two sections. The first incorporates a narrative from Ms. Scott; the second is derived from the researcher's analysis and interpretation of data from the study.     

Toward a functional learning system for Solomon Island secondary science classrooms

This paper uses a model of Melanesian Solomon Islanders' informal learning system derived from participant observation and interview data to analyse classroom interactions at the senior secondary level. Key learning strategies in the Melanesian informal learning system are observation, imitation, listening, participation and asking. Key contextual elements described pertain to the maintenance of interpersonal relationships, kin‐group and peer‐oriented learning, and epistemology, sociolinguistics and time orientation. This analysis is used to enhance the attainment of classroom goals through the development of a functional learning system for laboratory‐oriented science lessons comprising teaching strategies and classroom management techniques which incorporate particular elements of the Melanesian informal learning system. Evidence is presented supporting the selective use of observation, active imitation, listening and participation in a classroom context which maintains respect between participants and assigns roles to them in ways congruent with Melanesian cultural norms.     

Towards a science of motivated learning in technology-supported environments

This commentary reviews seven papers that study motivation with new media, contained in this special issue of Educational Technology Research & Development edited by Ruth Small. For each paper, this commentary summarizes exemplary contributions, offers an assessment of what is exciting, and suggests directions for future research. Some exciting contributions include using new media in an attempt to promote motivation such as game-making, collaborative wiki construction, and interaction with onscreen agents. Some important challenges for future research on motivation with new media are to develop testable theories and to collect evidence based on rigorous methodologies including evidence concerning the relation between motivation and learning outcomes     

Religious beliefs in science classrooms

The question of the relationship between science and religion assumes importance for many secondary school students of science, especially but not exclusively for those in Christian schools. Science as presented in many school classrooms is not as objective and value free as it might seem on first examination, nor does it represent adequately the range of beliefs about science held by students and teachers. This paper reports part of a larger research study into beliefs about science and religion held by students, teachers and clergy in a Lutheran secondary school. Results indicate that participants in the study was the relationship between science and religious belief in ways unforeseen and unappreciated by traditional school science programs. The stories of selected participants are told and they frame a discussion of implications of the study for science teaching.